KR102533169B1 - Carbon dioxide capture device with improved energy efficiency - Google Patents

Abstract

The present invention relates to a device for treating exhaust gas generated while operating a power plant (1). The device comprises: an absorption tower (10) contacting exhaust gas transferred to a chimney (1a) of a power plant (1) with an absorbent in a countercurrent manner and saturating the absorbent with carbon dioxide in the exhaust gas; a regeneration tower (20) exposing the carbon dioxide saturated absorbent produced by reaction in the absorption tower (10) to high temperature and separating and regenerating carbon dioxide and an absorbent; a steam supply line (30) supplying steam generated from a boiler (1c) to the regeneration tower (20) to operate a turbine (1b) of the power plant (1) and produce electricity; and a gas heat exchange unit (40) heat exchanging the exhaust gas of the power plant (1) with the carbon dioxide saturated absorbent transferred from the absorption tower (10) to the regeneration tower (20) to lower a temperature of the exhaust gas and heating the carbon dioxide saturated absorbent. According to the present invention, the steam generated to operate the turbine at the power plant is used as a heat source for the regeneration tower, and heat is exchanged between the exhaust gas discharged from the power plant and the saturated absorbent transferred from the absorption tower to the regeneration tower. Therefore, as the high temperature exhaust gas is cooled and the low temperature saturated absorbent is heated, overall operating costs required to capture carbon dioxide can be minimized.

Description

Carbon dioxide capture device with improved energy efficiency}

The present invention relates to a device for treating exhaust gas generated while operating a power plant, and more particularly, to use steam generated to operate a turbine in a power plant as a heat source for a regeneration tower, and then to absorb the exhaust gas discharged from the power plant. By exchanging heat with the saturated absorbent transferred from the tower to the regeneration tower, the high-temperature exhaust gas is cooled and the low-temperature saturated absorbent is heated, thereby improving energy efficiency to minimize the overall operating cost required for capturing carbon dioxide. It's about the capture device.

Along with industrialization, greenhouse gas emissions are continuously increasing, and various meteorological disasters such as abnormal temperature phenomena and sea level rise are occurring due to global warming.

Many countries around the world are making efforts to reduce greenhouse gas emissions in order to respond to global warming that continues to intensify. technology is being developed.

Carbon dioxide accounts for the largest portion of greenhouse gas emissions, and most of the carbon dioxide is emitted from industrial sites such as the energy sector, cement, steel, and chemical industries.

According to a report published by the IEA, carbon capture and storage (CCS) technology is expected to account for 12% by 2050, along with increased fuel efficiency and renewable energy related to greenhouse gas reduction. The importance of CCS technology, which directly removes it, as a future core technology for greenhouse gas reduction was emphasized.

These carbon dioxide capture technologies are classified into chemical absorption and physical absorption. Physical absorption is used when the partial pressure of gas components is high, and chemical absorption is effective when the partial pressure of carbon dioxide is low, such as in combustion exhaust gas.

A typical chemical absorption method is to selectively capture carbon dioxide by contacting an absorbent with exhaust gas at an appropriate temperature and pressure, and is composed of a device including an absorption tower, a regeneration tower, a reboiler, a pump, a blower, and the like.

Here, since the reboiler (steam generator) operated to generate steam in the regeneration tower consumes considerable energy, there is a problem in that carbon dioxide emission due to power consumption also increases.

Therefore, in order to improve this problem, as disclosed in Patent Document 1, a structure in which the heat of the steam condensate used to heat the carbon dioxide saturated absorbent in the regeneration tower is exchanged with the carbon dioxide saturated absorbent flowing into the regeneration tower to reduce operating costs is proposed. there is a bar

However, when the operation rate of the reboiler in the existing general collector is 100%, the energy saving efficiency of 97%, that is, 3%, is insufficient when heat exchange between absorbers is performed.

Therefore, there is a need for a plan that can drastically reduce the overall operating cost required to operate the collecting device.

Republic of Korea Patent Registration No. 10-1375645 Title of Invention: Carbon dioxide capture device using heat from regasifier steam condensate

The present invention has been proposed to solve the above problems, and steam generated to operate a turbine in a power plant is used as a heat source for a regeneration tower, followed by exhaust gas discharged from the power plant and a saturated absorbent transferred from the absorption tower to the regeneration tower. By exchanging heat with, the high-temperature exhaust gas is cooled and the low-temperature saturated absorbent is heated, thereby minimizing the overall operating cost required for capturing carbon dioxide. The purpose is to provide a carbon dioxide capture device with improved energy efficiency. .

The present invention relates to an apparatus for treating exhaust gas generated while operating a power plant, comprising: an absorption tower for saturating carbon dioxide in the exhaust gas into the absorbent by contacting the exhaust gas transferred to the chimney of the power plant with an absorbent in a countercurrent manner; a regeneration tower that exposes the carbon dioxide saturated absorbent generated by the reaction in the absorption tower to a high temperature to separate and regenerate carbon dioxide and the absorbent; a steam supply line supplying steam generated from a boiler to a regeneration tower in order to produce power by operating a turbine of the power plant; and a gas heat exchange unit for heat-exchanging the exhaust gas of the power plant with the saturated carbon dioxide absorbent transferred from the absorption tower to the regeneration tower to lower the temperature of the exhaust gas and heating the saturated carbon dioxide absorbent.

At this time, the absorption tower according to the present invention includes one or more absorption tower reactors in which the exhaust gas and the absorbent are introduced in a countercurrent flow and carbon dioxide in the exhaust gas is saturated in the absorbent; an absorption accelerating block disposed inside the absorbent reactor and increasing the reaction with the absorbent by dispersing the exhaust gas; an absorption tower storage that is disposed downstream of the absorption tower reactor and accommodates the carbon dioxide saturated absorbent in a predetermined capacity; It is characterized in that it consists of an absorption tower washing station disposed upstream of the absorption tower reactor and washing and cooling nitrogen and oxygen of the exhaust gas from which the carbon dioxide has been removed with washing water.

In addition, the absorption tower according to the present invention includes an absorption tower circulation line connected to the upper side of the absorption tower reaction station and the lower side of the absorption tower storage to circulate the absorbent; an absorption tower circulation pump interposed in the absorption tower circulation line to circulate the absorbent contained in the absorption tower storage; an absorption tower radiator interposed in the absorption tower circulation line to cool the circulated absorbent; Absorption tower transfer lines connected to the lower side of the absorption tower storage and to the gas heat exchanger and the regeneration tower to transfer the saturated absorbent; An absorption tower transfer pump interposed in the absorption tower transfer line to transfer the saturated absorbent contained in the absorption tower storage to a gas heat exchange unit and a regeneration tower; characterized in that it is configured.

In addition, the regeneration tower according to the present invention includes one or more regeneration tower separators in which the carbon dioxide saturated absorbent and steam are introduced in a countercurrent manner, and carbon dioxide saturated in the saturated absorbent is separated and recycled; a regeneration accelerating block disposed inside the regeneration tower separator and enhancing a reaction with steam by dispersing the saturated absorbent; a regeneration tower storage that is disposed downstream of the regeneration tower separator and accommodates the regenerated absorbent in a predetermined capacity; a steam supplier disposed downstream of the regeneration tower storage and generating and supplying steam to the regeneration tower separation station; a regeneration tower washing station disposed upstream of the regeneration tower separation station and washing and cooling the carbon dioxide separated from the saturated absorbent with washing water; a regeneration tower transfer line connected to the lower side of the regeneration tower storage and to the absorption tower to discharge the regenerated absorbent; It is characterized in that it consists of; a regeneration tower transfer pump interposed in the regeneration tower transfer line to transfer the regenerated absorbent contained in the regeneration tower storage to the absorption tower.

In addition, the gas heat exchange unit according to the present invention is disposed on the downstream side of the chimney, a gas blower for transporting the exhaust gas to the absorption tower; a gas heat exchanger disposed downstream of the gas blower and exchanging heat between the exhaust gas and the carbon dioxide saturated absorbent; a gas cooler disposed downstream of the gas heat exchanger and cooling the exhaust gas to a set temperature by contacting the cooling water; a high-temperature gas line connected to the chimney, the gas blower, and the gas heat exchanger to transport exhaust gas of 130° C. or higher; a medium-temperature gas line connected to the gas heat exchanger and the gas cooler to transport exhaust gas of 90° C. or less; It is characterized in that it consists of; a low-temperature gas line connected to the gas cooler and the absorption tower and through which the exhaust gas of 50 ° C. or less is transported.

In addition, the water absorbent according to the present invention is characterized in that an amine-based water content of 15% by weight or less, an amino acid salt, an inorganic salt, ammonia, or a mixture of two or more thereof.

In addition, the regeneration tower according to the present invention is characterized by further comprising a regeneration tower radiator interposed in the regeneration tower transfer line to cool the regenerated absorbent transferred to the absorption tower to 50 ° C or less.

In addition, the regeneration tower according to the present invention heat-exchanges the regenerated absorbent transferred to the absorption tower through the regeneration tower transfer line and the saturated absorbent transferred from the absorption tower to the gas heat exchange unit to lower the temperature of the regenerated absorbent and heat the saturated absorbent. It is characterized in that the absorbent heat exchanger; is further configured.

First, the present invention configures a steam supply line for supplying steam generated to operate a turbine in a power plant as a heat source of a regeneration tower, thereby increasing the operation rate of a steam supplier for generating steam to separate carbon dioxide from a saturated absorbent in a regeneration tower. There are effects that can be significantly reduced or omitted.

Second, the present invention configures a gas heat exchange unit that heats the exhaust gas discharged from the power plant and the saturated absorbent transferred from the absorption tower to the regeneration tower, so that the high-temperature exhaust gas is cooled to a low temperature before being transferred to the absorption tower, so that the cooling water as well as the cooling water Energy required for cooling can be reduced, and as the low-temperature saturated absorbent is transferred to the absorption tower in a state of being heated to a high temperature, the amount of steam used can be reduced, thereby reducing overall operating costs.

In addition to the effects described above, specific effects of the present invention will be described together while explaining specific details for carrying out the present invention.

1 is a system diagram showing a carbon dioxide capture device according to the present invention as a whole.
2 is a system diagram showing an enlarged absorption tower of the carbon dioxide capture device according to the present invention.
3 is a system diagram showing an enlarged regeneration tower of the carbon dioxide capture device according to the present invention.
4 is a system diagram showing an enlarged gas heat exchanger of the carbon dioxide capture device according to the present invention.
5 is a system diagram showing a carbon dioxide capture device according to a modification of the present invention as a whole.

Hereinafter, various embodiments of this document will be described with reference to the accompanying drawings. However, this is not intended to limit the technology described in this document to specific embodiments, and it should be understood that it includes various modifications, equivalents, and/or alternatives of the embodiments of this document. In connection with the description of the drawings, like reference numerals may be used for like elements.

In addition, expressions such as “first,” “second,” etc. used in this document may modify various components regardless of order and/or importance, and to distinguish one component from another. It is used only and does not limit the corresponding components. For example, 'first part' and 'second part' may indicate different parts regardless of order or importance. For example, a first element may be named a second element without departing from the scope of rights described in this document, and similarly, the second element may also be renamed to the first element.

In addition, terms used in this document are only used to describe a specific embodiment, and may not be intended to limit the scope of other embodiments. Singular expressions may include plural expressions unless the context clearly dictates otherwise. Terms used herein, including technical or scientific terms, may have the same meaning as commonly understood by a person of ordinary skill in the technical field described in this document. Among the terms used in this document, terms defined in a general dictionary may be interpreted as having the same or similar meaning as the meaning in the context of the related art, and unless explicitly defined in this document, an ideal or excessively formal meaning. not be interpreted as In some cases, even terms defined in this document cannot be interpreted to exclude the embodiments of this document.

The present invention relates to a device for treating exhaust gas generated while operating a power plant (1), and as shown in FIG. 1, an absorption tower (10), a regeneration tower (20), a steam supply line (30), and a gas heat exchanger (40) It is a carbon dioxide capture device with improved energy efficiency.

At this time, the absorbent and the regenerated absorbent referred to in the present invention refer to a state in which carbon dioxide is not saturated, and the saturated absorbent refers to a state in which carbon dioxide is saturated.

In addition, the upstream side and the downstream side mentioned in the description do not indicate positions such as up/down or up/down, but indicate positions according to the flow of gas, liquid, heat, and the like.

First, the absorption tower 10 according to the present invention saturates the absorbent with carbon dioxide of the exhaust gas by contacting the exhaust gas transferred to the chimney 1a of the power plant 1 with the absorbent in a countercurrent manner, as shown in FIG.

As shown in FIG. 2, the absorption tower 10 is composed of an absorption tower reactor 11, an absorption accelerating block 12, an absorption tower storage 13, and an absorption tower washing station 14.

It is composed of an absorption tower circulation line 15, an absorption tower circulation pump 16, an absorption tower radiator 17, an absorption tower transfer line 18, and an absorption tower transfer pump 19.

The absorption tower reactor 11 is a chamber in which the exhaust gas and the absorbent are introduced in a counter-flow manner, and carbon dioxide in the exhaust gas is saturated in the absorbent.

Two or more absorption tower reactors 11 may be configured, and as shown in the drawing, they may be configured to communicate in multiple stages or may be configured independently.

The absorption accelerating block 12 is disposed inside the absorption tower reactor 11 to increase the reaction between the exhaust gas and the absorbent.

The absorption accelerating block 12 is made of a porous metal material and disperses the countercurrent exhaust gas and the absorbent while colliding with each other to increase contact.

The absorption tower storage 13 is disposed on the downstream side of the absorption tower reactor 11 and accommodates a carbon dioxide saturated absorbent in a predetermined capacity.

Here, an absorbent or a regenerated absorbent is accommodated in the absorption tower storage 13 before exhaust gas is collected.

The absorption tower washing station 14 is disposed upstream of the absorption tower reactor 11 to wash and cool the nitrogen and oxygen of the exhaust gas from which carbon dioxide has been removed with washing water.

A gas discharge line for discharging nitrogen and oxygen in the exhaust gas into the air or storing it in a container is connected to the upper side of the absorption tower washing station 14.

The absorption tower circulation line 15 circulates the absorbent at the beginning of operation or the regenerated absorbent, and is connected to the upper side of the absorption tower reactor 11 and the lower side of the absorption tower storage 13.

The absorption tower circulation pump 16 is interposed in the absorption tower circulation line 15 to circulate the absorbent contained in the absorption tower storage 13.

The absorption tower radiator 17 is interposed in the absorption tower circulation line 15 to cool the circulated absorbent.

Here, the absorbent must continuously counter-flow with the exhaust gas for a certain period of time to saturate the carbon dioxide at a high concentration.

That is, the absorption tower radiator 17 cools the absorbent heated by continuous contact with exhaust gas of 60°C or higher to 60°C or less.

The absorption tower transfer line 18 transfers the saturated absorbent and is connected to the lower side of the absorption tower storage 13 and the upper side of the gas heat exchanger 42 and the regeneration tower separator 21, respectively.

The absorption tower transfer pump 19 is interposed in the absorption tower transfer line 18 to transfer the saturated absorbent contained in the absorption tower storage 13 to the regeneration tower separation station 21 via the gas heat exchanger 42.

At this time, the absorbent used in the absorption tower 10 may be an amine-based water content of 15% by weight or less, an amino acid salt, an inorganic salt, ammonia, or a mixture of two or more thereof.

Next, the regeneration tower 20 according to the present invention exposes the carbon dioxide saturated absorbent generated by the reaction in the absorption tower 10 to a high temperature as shown in FIG. 1 to separate and regenerate carbon dioxide and the absorbent.

As shown in FIG. 3, the regeneration tower 20 includes a regeneration tower separator 21, a regeneration promotion block 22, a regeneration tower storage 23, a steam supplier 24, a regeneration tower washing station 25, It consists of a regeneration tower transfer line 26, a regeneration tower transfer pump 27, and a regeneration tower radiator 28.

The regeneration tower separator 21 is a chamber in which carbon dioxide saturated absorbent and steam are introduced in a countercurrent flow to separate and regenerate carbon dioxide saturated in the saturated absorbent.

Two or more of these regeneration tower separators 21 may be configured, and as shown in the drawing, they may be configured to communicate in multiple stages or may be configured independently.

The regeneration accelerator block 22 is disposed inside the regeneration tower separator 21 to increase the reaction between the saturated absorbent and steam.

The regeneration accelerating block 22 is made of a porous metal material and increases heat transfer by dispersing steam while colliding with a saturated absorbent flowing in the opposite direction.

The regeneration tower storage 23 is disposed on the downstream side of the regeneration tower separation station 21 and accommodates a regenerated absorbent in a predetermined capacity.

The steam supplier 24 is a reboiler and is disposed downstream of the regeneration tower storage 23 to generate and supply steam to the regeneration tower separation station 21.

Since the steam supplier 24 receives steam from the steam supply line 30, the supplied 200° C. steam is continuously supplied while reboiling the saturated absorbent liquid to become 100° C. condensate and continuously discharged.

The regeneration tower washing station 25 is disposed upstream of the regeneration tower separation station 21 to wash carbon dioxide separated from the saturated absorbent with washing water.

A gas discharge line is connected to the upper side of the regeneration tower washing station 25 to separate the separated carbon dioxide from water with a condenser and store the carbon dioxide.

The regeneration tower transfer line 26 supplies the regenerated absorbent to the absorption tower 10, and is connected to the lower side of the regeneration tower storage 23 and the upper side of the absorption tower reactor 11.

The regeneration tower transfer pump 27 is interposed in the regeneration tower transfer line 26 to transfer the regenerated absorbent contained in the regeneration tower storage 23 to the absorption tower reactor 11.

The regeneration tower radiator 28 is interposed in the regeneration tower transfer line 26 to cool the regenerated absorbent transferred to the absorption tower reactor 11 to a temperature of 60°C or less.

That is, the regeneration tower radiator 28 cools the regenerated absorbent heated to 80° C. or higher by steam to 60° C. or lower, the operating temperature of the absorption tower 10.

Subsequently, the steam supply line 30 according to the present invention supplies steam generated from the boiler 1c to the regeneration tower 20 to generate electricity by operating the turbine 1b of the power plant 1 as shown in FIG.

That is, one end of the steam supply line 30 is connected to the steam outlet of the boiler 1c, and the other end is connected to the steam supplier 24.

Here, the other end of the steam supply line 30 may be connected in parallel to the lower side of the regeneration tower storage 23 together with the steam supply 24.

Of course, when the steam supplier 24 is omitted, it is connected solely to the lower side of the regeneration tower storage 23.

Finally, the gas heat exchanger 40 according to the present invention exchanges heat with the saturated absorbent transferred from the absorption tower 10 to the regeneration tower 20 for the exhaust gas of the power plant 1 as shown in FIG.

As shown in FIG. 4, the gas heat exchanger 40 includes a gas blower 41, a gas heat exchanger 42, a gas cooler 43, a high-temperature gas line 44, a medium-temperature gas line 45, and a low-temperature gas It consists of line 46.

The gas blower 41 is disposed on the downstream side of the chimney 1a and transfers the exhaust gas to the upper side of the absorption tower storage 13.

The gas heat exchanger 42 is disposed on the downstream side of the blower 41 to exchange heat between the exhaust gas and the saturated absorbent.

That is, the gas heat exchanger 42 heat-exchanges the exhaust gas and the saturated absorbent to lower the temperature of the exhaust gas and heats the carbon dioxide saturated absorbent.

The gas cooler 43 is disposed on the downstream side of the gas heat exchanger 42 and cools the exhaust gas to a set temperature by contacting the cooling water.

The high-temperature gas line 44 transports exhaust gas of 130° C. or higher, and is connected to the chimney 1a, the gas blower 41, and the gas heat exchanger 42.

The medium-temperature gas line 45 transports exhaust gas of 100° C. or less, and is connected to the gas heat exchanger 42 and the gas cooler 43.

The low-temperature gas line 46 transfers exhaust gas having a temperature of 50° C. or less, and is connected to the upper side of the gas cooler 43 and the absorption tower storage 13.

That is, the exhaust gas of 130° C. or more transferred from the chimney 1a is cooled to 100° C. or less while passing through the gas heat exchanger 42, and the saturable absorbent is heated to 100° C. or more.

The exhaust gas cooled to 100°C or less is cooled to 50°C or less while passing through the gas cooler 43 and supplied to the absorption tower storage 13.

Hereinafter, the core of the process of capturing carbon dioxide by the collecting device according to the present invention is as follows.

First, the exhaust gas of the power plant 1 is supplied to the absorption tower 10 via the gas heat exchanger 40, and the steam of the power plant 1 is supplied to the regeneration tower 20.

The exhaust gas supplied to the absorption tower 10 is contacted with the circulating absorbent in a countercurrent manner so that carbon dioxide in the exhaust gas is saturated in the absorbent.

The saturated absorbent saturated with carbon dioxide at a high concentration is heated to 100° C. or higher while passing through the gas heat exchanger 40 and then supplied to the regeneration tower 20.

Here, exhaust gas that has passed through the gas heat exchanger 40 is cooled to 100° C. or lower due to heat exchange with the saturated absorbent.

Therefore, the energy required to cool the exhaust gas to 60° C., which is the operating temperature of the absorption tower 10, can be greatly reduced.

The saturated absorbent supplied to the regeneration tower 20 is contacted with the steam of the power plant 1 in a countercurrent manner so that the saturated absorbent and carbon dioxide are separated.

Here, since the saturable absorbent is heated to 100° C. or higher, it is possible to significantly reduce the energy required to heat the saturated absorbent to 140° C., which is the operating temperature of the regeneration tower 20, that is, the amount of steam supplied.

Nitrogen and oxygen discharged from the absorption tower 10 and carbon dioxide discharged from the regeneration tower 20 are stored in a storage tank by being connected to a gas discharge line that separates carbon dioxide and water by a condenser and stores the carbon dioxide.

Meanwhile, the collecting device according to the present invention may be configured with an absorbent heat exchanger 29 instead of the regeneration tower radiator 28 as shown in FIG. 5 .

That is, the absorbent heat exchanger 29 is interposed in the regeneration tower transfer line 26 and transfers the regenerated absorbent transferred from the regeneration tower 20 to the absorption tower 10 and the gas heat exchanger 40 from the absorption tower 10. The transferred saturated absorbent undergoes heat exchange.

Therefore, since the regenerated absorbent is lowered to 60 ° C or lower and the saturated absorbent is heated to 60 ° C or higher, the saturated absorbent passing through the gas heat exchanger 40 can quickly reach 130 ° C, which is the temperature of the exhaust gas. ) can be omitted, and the amount of steam supplied from the power plant 1 to the regeneration tower 20 can be significantly reduced, thereby minimizing the decrease in power generation efficiency.

Although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and is common in the art to which the present invention pertains without departing from the gist of the present invention claimed in the claims. Of course, various modifications are possible by those with knowledge of, and these modified embodiments should not be individually understood from the technical spirit or perspective of the present invention.

1: power plant
1a: chimney
1b: Turbine
1c: Boiler
10: absorption tower
11: absorption tower reactor
12: absorption promotion block
13: absorption tower storage
14: Absorption tower washing station
15: absorption tower circulation line
16: absorption tower circulation pump
17: Absorption tower radiator
18: absorption tower transfer line
19: absorption tower transfer pump
20: regeneration tower
21: Regeneration Tower Separation Station
22: regeneration promotion block
23: regeneration tower storage
24: steam supply
25: Regeneration Tower Washing Station
26: regeneration tower discharge line
27: regeneration tower transfer pump
28: Regenerative Top Radiator
29: absorbent heat exchanger
30: steam supply line
40: gas heat exchange unit
41: gas blower
42: gas heat exchanger
43: gas cooler
44: hot gas line
45: medium temperature gas line
46: low temperature gas line

Claims (7)

In the device for treating exhaust gas generated while operating the power plant (1),
an absorption tower (10) for saturating the absorbent with carbon dioxide in the exhaust gas by contacting the exhaust gas transported to the chimney (1a) of the power plant (1) with the absorbent in a countercurrent manner;
a regeneration tower (20) that regenerates the carbon dioxide saturated absorbent produced by the reaction in the absorption tower (10) by exposing it to a high temperature to separate and regenerate carbon dioxide and the absorbent;
a steam supply line 30 supplying steam generated from the boiler 1c to the regeneration tower 20 to produce power by operating the turbine 1b of the power plant 1;
A gas heat exchange unit 40 for heat-exchanging the exhaust gas of the power plant 1 with the carbon dioxide saturated absorbent transferred from the absorption tower 10 to the regeneration tower 20 to lower the temperature of the exhaust gas and heating the carbon dioxide saturated absorbent; including,
The regeneration tower 20,
one or more regeneration tower separators 21 in which the carbon dioxide saturated absorbent and steam are introduced in a countercurrent flow, and the carbon dioxide saturated in the saturated absorbent is separated and recycled;
a regeneration promoting block 22 disposed inside the regeneration tower separator 21 and enhancing a reaction with steam by dispersing the saturated absorbent;
a regeneration tower storage 23 disposed downstream of the regeneration tower separator 21 and accommodating a regenerated absorbent in a predetermined capacity;
a steam supplier 24 disposed downstream of the regeneration tower storage 23 and generating and supplying steam to the regeneration tower separation station 21;
a regeneration tower washer 25 disposed upstream of the regeneration tower separator 21 and washing and cooling the carbon dioxide separated from the saturated absorbent with washing water;
a regeneration tower transfer line 26 connected to the lower side of the regeneration tower storage 23 and to the absorption tower 10 to discharge the regenerated absorbent;
a regeneration tower transfer pump 27 interposed in the regeneration tower transfer line 26 to transfer the regenerated absorbent contained in the regeneration tower storage 23 to the absorption tower 10;
Carbon dioxide capture device with improved energy efficiency, characterized in that consisting of. The method of claim 1,
The absorption tower 10,
one or more absorption tower reactors (11) into which the exhaust gas and the absorbent are introduced in a counter-current fashion and carbon dioxide in the exhaust gas is saturated in the absorbent;
an absorption accelerating block 12 disposed inside the absorption tower reactor 11 and increasing the reaction with the absorbent by dispersing the exhaust gas;
an absorption tower storage 13 disposed downstream of the absorption tower reactor 11 and accommodating the saturated carbon dioxide absorbent in a predetermined capacity;
an absorption tower washing station 14 disposed upstream of the absorption tower reactor 11 and washing and cooling nitrogen and oxygen in the exhaust gas from which carbon dioxide has been removed with washing water;
Carbon dioxide capture device with improved energy efficiency, characterized in that consisting of. The method of claim 2,
The absorption tower 10,
an absorption tower circulation line 15 connected to the upper side of the absorption tower reactor 11 and the lower side of the absorption tower storage 13 to circulate the absorbent;
an absorption tower circulation pump 16 interposed in the absorption tower circulation line 15 to circulate the absorbent contained in the absorption tower storage 13;
an absorption tower radiator 17 interposed in the absorption tower circulation line 15 to cool the circulated absorbent;
an absorption tower transfer line 18 connected to the lower side of the absorption tower storage 13, the gas heat exchanger 40, and the regeneration tower 20 to transfer the saturated absorbent;
an absorption tower transfer pump 19 interposed in the absorption tower transfer line 18 to transfer the saturated absorbent contained in the absorption tower storage 13 to the gas heat exchanger 40 and the regeneration tower 20;
A carbon dioxide capture device with improved energy efficiency, characterized in that configured. delete The method of claim 1,
The gas heat exchanger 40,
a gas blower 41 disposed on the downstream side of the chimney 1a and transporting the exhaust gas to the absorption tower 10;
a gas heat exchanger (42) disposed on a downstream side of the gas blower (41) to exchange heat between the exhaust gas and the carbon dioxide saturated absorbent;
a gas cooler (43) disposed downstream of the gas heat exchanger (42) and cooling the exhaust gas to a set temperature by contacting the cooling water;
a high-temperature gas line 44 connected to the chimney 1a, the gas blower 41, and the gas heat exchanger 42 to transport exhaust gas of 130° C. or higher;
a medium-temperature gas line (45) connected to the gas heat exchanger (42) and the gas cooler (43) through which exhaust gas of 90° C. or less is transported;
a low-temperature gas line (46) connected to the gas cooler (43) and the absorption tower (10) through which exhaust gas of 50° C. or less is transported;
Carbon dioxide capture device with improved energy efficiency, characterized in that consisting of. The method of claim 1,
The absorbent is an amine-based water content of 15% by weight or less, an amino acid salt, an inorganic salt, ammonia, or a carbon dioxide capture device with improved energy efficiency, characterized in that a mixture of two or more thereof. The method of claim 1,
The regeneration tower 20,
a regeneration tower radiator 28 interposed in the regeneration tower transfer line 26 to cool the regenerated absorbent transferred to the absorption tower 10 to a temperature of 50° C. or lower;
A carbon dioxide capture device with improved energy efficiency, characterized in that further configured.

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